msmbuilder.decomposition.tICA¶

class msmbuilder.decomposition.tICA(n_components=None, lag_time=1, shrinkage=None, weighted_transform=False, kinetic_mapping=False)¶

Time-structure Independent Component Analysis (tICA)

Linear dimensionality reduction using an eigendecomposition of the time-lag correlation matrix and covariance matrix of the data and keeping only the vectors which decorrelate slowest to project the data into a lower dimensional space.

Parameters:

n_components : int, None

Number of components to keep.

lag_time : int

Delay time forward or backward in the input data. The time-lagged correlations is computed between datas X[t] and X[t+lag_time].

shrinkage : float, default=None

The covariance shrinkage intensity (range 0-1). If shrinkage is not specified (the default) it is estimated using an analytic formula (the Rao-Blackwellized Ledoit-Wolf estimator) introduced in [5].

weighted_transform : bool, default=False

Deprecated. Please use kinetic_mapping.

kinetic_mapping : bool, default=False

If True, weigh the projections by the tICA eigenvalues, yielding

kinetic distances as described in [6].

Notes

This method was introduced originally in [R16], and has been applied to the analysis of molecular dynamics data in [R13], [R14], and [R15]. In [R13] and [R14], tICA was used as a dimensionality reduction technique before fitting other kinetic models.

Attributes

components_

(array-like, shape (n_components, n_features)) Components with maximum autocorrelation. offset_correlation_ : array-like, shape (n_features, n_features) Symmetric time-lagged correlation matrix, \(C=E[(x_t)^T x_{t+lag}]\). eigenvalues_ : array-like, shape (n_features,) Eigenvalues of the tICA generalized eigenproblem, in decreasing order. eigenvectors_ : array-like, shape (n_components, n_features) Eigenvectors of the tICA generalized eigenproblem. The vectors give a set of “directions” through configuration space along which the system relaxes towards equilibrium. Each eigenvector is associated with characteritic timescale :math:`-

rac{lag_time}{ln lambda_i}, where \(lambda_i\) is

the corresponding eigenvector. See [2] for more information. means_ : array, shape (n_features,) The mean of the data along each feature n_observations_ : int Total number of data points fit by the model. Note that the model is “reset” by calling fit() with new sequences, whereas partial_fit() updates the fit with new data, and is suitable for online learning. n_sequences_ : int Total number of sequences fit by the model. Note that the model is “reset” by calling fit() with new sequences, whereas partial_fit() updates the fit with new data, and is suitable for online learning. timescales_ : array-like, shape (n_features,) The implied timescales of the tICA model, given by -offset / log(eigenvalues)

Methods

`fit`(sequences[, y])	Fit the model with a collection of sequences.
`fit_transform`(sequences[, y])	Fit the model with X and apply the dimensionality reduction on X.
`get_params`([deep])	Get parameters for this estimator.
`partial_fit`(X)	Fit the model with X.
`partial_transform`(features)	Apply the dimensionality reduction on X.
`score`(sequences[, y])	Score the model on new data using the generalized matrix Rayleigh quotient
`set_params`(**params)	Set the parameters of this estimator.
`summarize`()	Some summary information.
`transform`(sequences)	Apply the dimensionality reduction on X.

__init__(n_components=None, lag_time=1, shrinkage=None, weighted_transform=False, kinetic_mapping=False)¶

Methods

`__init__`([n_components, lag_time, ...])
`fit`(sequences[, y])	Fit the model with a collection of sequences.
`fit_transform`(sequences[, y])	Fit the model with X and apply the dimensionality reduction on X.
`get_params`([deep])	Get parameters for this estimator.
`partial_fit`(X)	Fit the model with X.
`partial_transform`(features)	Apply the dimensionality reduction on X.
`score`(sequences[, y])	Score the model on new data using the generalized matrix Rayleigh quotient
`set_params`(**params)	Set the parameters of this estimator.
`summarize`()	Some summary information.
`transform`(sequences)	Apply the dimensionality reduction on X.

Attributes

`components_`
`covariance_`
`eigenvalues_`
`eigenvectors_`
`means_`
`offset_correlation_`
`score_`	Training score of the model, computed as the generalized matrix,
`timescales_`

fit(sequences, y=None)¶

Fit the model with a collection of sequences.

This method is not online. Any state accumulated from previous calls to fit() or partial_fit() will be cleared. For online learning, use partial_fit.

Parameters:

sequences: list of array-like, each of shape (n_samples_i, n_features)

Training data, where n_samples_i in the number of samples in sequence i and n_features is the number of features.

y : None

Ignored

Returns:

self : object

Returns the instance itself.

fit_transform(sequences, y=None)¶

Fit the model with X and apply the dimensionality reduction on X.

This method is not online. Any state accumulated from previous calls to fit() or partial_fit() will be cleared. For online learning, use partial_fit.

Parameters:

sequences: list of array-like, each of shape (n_samples_i, n_features)

Training data, where n_samples_i in the number of samples in sequence i and n_features is the number of features.

y : None

Ignored

Returns:

sequence_new : list of array-like, each of shape (n_samples_i, n_components)

get_params(deep=True)¶

Get parameters for this estimator.

Parameters:

deep: boolean, optional

If True, will return the parameters for this estimator and contained subobjects that are estimators.

Returns:

params : mapping of string to any

Parameter names mapped to their values.

partial_fit(X)¶

Fit the model with X.

This method is suitable for online learning. The state of the model will be updated with the new data X.

Parameters:

X: array-like, shape (n_samples, n_features)

Training data, where n_samples in the number of samples and n_features is the number of features.

Returns:

self : object

Returns the instance itself.

partial_transform(features)¶

Apply the dimensionality reduction on X.

Parameters:

features: array-like, shape (n_samples, n_features)

Training data, where n_samples in the number of samples and n_features is the number of features. This function acts on a single featurized trajectory.

Returns:

sequence_new : array-like, shape (n_samples, n_components)

TICA-projected features

Notes

This function acts on a single featurized trajectory.

score(sequences, y=None)¶

Score the model on new data using the generalized matrix Rayleigh quotient

Parameters:

sequences : list of array, each of shape (n_samples_i, n_features)

Test data. A list of sequences in afeature space, each of which is a 2D array of possibily different lengths, but the same number of features.

Returns:

gmrq : float

Generalized matrix Rayleigh quotient. This number indicates how well the top n_timescales+1 eigenvectors of this tICA model perform as slowly decorrelating collective variables for the new data in sequences.

References

[R19]

McGibbon, R. T. and V. S. Pande, “Variational cross-validation of slow dynamical modes in molecular kinetics” J. Chem. Phys. 142, 124105 (2015)

score_¶: Training score of the model, computed as the generalized matrix, Rayleigh quotient, the sum of the first n_components eigenvalues

set_params(**params)¶

Set the parameters of this estimator.

The method works on simple estimators as well as on nested objects (such as pipelines). The former have parameters of the form <component>__<parameter> so that it’s possible to update each component of a nested object.

Returns:	self

summarize()¶: Some summary information.

transform(sequences)¶

Apply the dimensionality reduction on X.

Parameters:

sequences: list of array-like, each of shape (n_samples_i, n_features)

Training data, where n_samples_i in the number of samples in sequence i and n_features is the number of features.

Returns:

sequence_new : list of array-like, each of shape (n_samples_i, n_components)